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Manufacturing Process Planning in Set-BasedConcurrent Engineering Paradigm
Endris Kerga, Marco Taisch, Sergio Terzi
To cite this version:Endris Kerga, Marco Taisch, Sergio Terzi. Manufacturing Process Planning in Set-Based ConcurrentEngineering Paradigm. 9th International Conference on Product Lifecycle Management (PLM), Jul2012, Montreal, QC, Canada. pp.158-169, �10.1007/978-3-642-35758-9_14�. �hal-01526117�
Manufacturing Process Planning in Set-Based
Concurrent Engineering Paradigm
Kerga Endris1, Taisch Marco
1, Terzi Sergio
2
1Politecnico di Milano, Department of Economics, Management and Industrial Engineering,
Piazza Leonardo da Vinci 32, Milano, 20133, Italy
[email protected], [email protected] 2Università degli Studi di Bergamo, Department of Industrial Engineering Viale
Marconi 5, Dalmine (BG) 24044, Italy
Abstract. The integration of manufacturing planning activities into early design
decisions is paramount. Manufacturing constraints and opportunities should be
investigated early in a product development (PD) stages to launch products suc-
cessfully. Set-based concurrent engineering (SBCE) paradigm is pronounced in
literature and believed to form the foundation of lean thinking in PD. In SBCE,
alternative product-subsystems are explored simultaneously and weak design
choices are progressively eliminated as more knowledge about manufacturabil-
ity becomes known. However, there is a methodological gap on how to execute
SBCE in practice and integrate manufacturing process planning.
This paper aims at conceptualizing the requirements to start manufacturing
planning in the realm of SBCE paradigm. At the same time, the paper proposes
a dialogue mechanism through which designers and manufacturing process
planners are able to explore and evaluate alternative conceptual designs and
process plans in parallel. Moreover, the methodology enables design and pro-
cess knowledge to be effectively integrated for a better decision making.
Keywords. Product Development (PD), Set-Based Concurrent Engineering
(SBCE), Manufacturing Process Planning.
1 Introduction to Set-based Concurrent Engineering (SBCE)
The traditional approach to develop a product concept, shown in the left part of Figure
1, typically starts with breaking the product down into subsystem, defining detailed
requirements for each module and deriving a small number of alternative solutions
which are suited to meet the initial requirements. Engineers then quickly assess the
solutions and select the most promising one to be pursued in the further PD process.
For the selected solution they develop drafts, build prototypes and conduct tests to
more and more specify the particular alternative. This process, however, rarely turns
out to be linear in nature. Usually, when specifying the module, engineers discover
that the particular specification chosen does not meet the requirements formulated at
the beginning because of manufacturability and other uncertainties. They then go
through iterative loops to either modify the concept until it satisfies their particular
need or start the process over by selecting a completely different alternative. Because
of its iterative nature where engineers move from point to point in the realm of possi-
ble designs, this paradigm has been termed point-based concurrent engineering
(PBCE) [1] and [2].
Fig. 1. Comparison between Point and Set-Based Concurrent Engineering
An alternative to the PBCE is set-based concurrent engineering (SBCE), the general
systematic of which is depicted in the right part of Figure 1. SBCE was first used by
Toyota [1]. Like PBCE, SBCE starts with dividing the product into small subsystems
and modules. However, unlike in PBCE, no detailed requirements are defined for
these subsystems. Instead, engineers only identify broad targets for every module.
Based on these general objectives, a much larger number of alternative solutions for
every component are developed early in the process. Designers design, test and ana-
lyze multiple solutions for every subsystem in parallel [3]. Unless designers have
sufficient knowledge to eliminate an alternative, it will be kept for further investiga-
tion.
SBCE is more advantageous compared to PBCE. First, it is a known fact that de-
sign reworks increase as a project approaches production launch, once resources have
already been committed. Therefore, front-loading the PD process by exploring alter-
natives early in the process instead of iterating in later stages is likely to reduce the
overall cost of PD [4]. Second, late engineering changes cause disruption in the over-
all schedule of the project, and cause unpredictability in the downstream activities [5].
SBCE’s principle of delaying decision makes sense for designers to avoid disruptions
of process flow. Third, quality and innovation level improved by adopting SBCE.
Exploring alternative design solutions and studying the feasibilities using proven data
and knowledge at early stages support engineers to find more innovative and robust
solutions compared to PBCE [1], [2], and [4].
To explore alternative design solutions and converge into an optimal, manufactur-
ability knowledge should be integrated systematically into SBCE process. However,
there is still no formal methodology aimed at integrating SBCE paradigm and manu-
facturability. Among others, questions that need to be answered include: How can
designers be made aware of manufacturing capabilities and constraints in SBCE para-
digm? How manufacturing planning can be executed in parallel with SBCE process?
This paper first tries to set the requirements of SBCE to start manufacturing plan-
ning (Section 2). Then, in Section 3, process planning literature has been explored to
gain insight on how process planning can be executed in early phase of design. In
Section 4, a methodological proposal is presented to answer the questions posed be-
fore. The proposed methodology is aimed at creating a dialogue mechanism through
which product designers and manufacturing planners exchange knowledge about al-
ternative designs and process plans. Besides, the methodology will be a support to
choose an optimal solution from design and manufacturing perspectives. Finally,
conclusion and future plans are briefed in section 5.
2 SBCE Requirements to start Manufacturing Process
Planning
After investigating extensively the Toyota’s product development process, Sobek
et.al. [2], summarized the principles of SBCE as shown in Figure 2.
Fig. 2. Principles of Toyota’s SBCE, modified from [2]
─ Map Design space
“Map the design space” is how Toyota develops and characterizes sets of alternatives
used in the SBCE process. In PD, Toyota applies this principle at component, sub-
system and full product levels. Basically, the principle states that different functions
involved in a PD should explore set of possible design alternatives from their own
perspectives. Further, functions should communicate their feasible designs to other
functions. The example in Figure 3 illustrates the key characteristics of SBCE. In Part
A, the design and manufacturing functions define broad sets of feasible solutions from
their respective areas of expertise.
─ Evaluate concept sets progressively through integration
Once the feasible regions from different functions are defined, this principle states
that functions should eliminate solutions which are proved to be infeasible from other
functions’ perspectives. However, unless there are sufficient data or knowledge to
eliminate an alternative design it should be kept as an alternative. This principle
makes SBCE different from PBCE. In the latter case, designers quickly select only
one solution they think it is feasible without having sufficient data and knowledge to
do so. Once that design proved to be infeasible late in a process, rework and process
disruption emerges (as usually happens in practice [6]). In contrast, SBCE advocates
delaying such decisions till enough knowledge is gathered through testing, simula-
tions, and integrations. In Part B of Figure 3, for example, design engineers smoothly
refines the set over time by eliminating ideas not feasible from manufacturing per-
spective and vice versa. And, only feasible solutions will be taken for further devel-
opment.
─ Concept convergence
As a design process matures and weak design solutions are eliminated through time,
other functions should have also continually eliminate their infeasible plans in paral-
lel. At a more detail phase, keeping wide design space is not recommendable both for
efficiency and communication reasons. Keeping alternative designs can causes extra
costs for the company to develop those concepts which might be not feasible in the
future. Moreover, it helps other functions to base their planning activities on a robust
design concept. Therefore, there should be a point at which optimal designs should be
selected. As shown in Part C and D of Figure 3, although some uncertainty remains at
latter phase of SBCE, design and manufacturing functions can agree on a rough de-
sign concept and a process plan.
The three principles of SBCE taken from Toyota PD sound logical and efficient.
Moreover, among the many reasons for the outstanding performance records of Toyo-
ta PD, SBCE is mentioned as one of the key strategy [1], [2], [3], and [4]. To execute
SBCE in practice though a formal procedure of exchanging information and
knowledge between functions is required. Since manufacturability information is
critical to execute SBCE, this paper focuses on formalizing the integration between
SBCE design process with manufacturing process planning. A methodological ap-
proach is also suggested to dialogue both functions to effectively explore and con-
verge into an optimal design and a process plan.
Based on the above principles, we identified the following key requirements that
are needed to integrate design and manufacturing under SBCE paradigm:
Integration between design and manufacturing should start at concept phase of
design,
Explore multiple set of solutions from design and manufacturing perspectives,
Early communication about sets, based on preliminary design information,
Impose minimum constraints to manufacturing and deliberately delaying specifica-
tions,
Narrow sets gradually while increasing details until an optimal design and manu-
facturing plan are found.
These requirements have significant implications for manufacturing process plan-
ning activities. Traditionally, process planning starts late in PD process or at detail
design stages once a CAD model is finished. As a consequence, manufacturability
problems then emerge causing delays and additional costs. Moreover, because de-
sign decisions are already been made, process planners traditionally cannot explore
potential process alternatives as early as possible [2], [7]. Therefore, the integration
of SBCE design strategy demands a new look on how process planning activities
are done. Furthermore, a new methodology is needed that enables designers and
process planers to explore and converge into optimal solution at early phase of de-
sign.
Fig. 3. Example of integration between design and manufacturing in SBCE paradigm [2]
3 Manufacturing Process Planning at Conceptual Design
Phases
A manufacturing process planning is a method of selecting primary and secondary
processes such as shaping, joining, or finishing a material. Also include selection of
supporting processes such a fixture scheme, cutting conditions, etc. It is important to
choose the right process-route at an early stage in the design before the cost-penalty
of making changes becomes large [7]. A single component might go through several
of those manufacturing processes (process-chains) to be finished. However, choosing
the right process chains is not an easy task at conceptual phase of design. Because,
only preliminary design information are available about the material, configuration,
shape, etc. Therefore, at conceptual design stage there are many unpredictable factors
in manufacturability, quality, reliability, serviceability [8]. As a result, process evalua-
tion for a design is usually taken place at latest stages of a design and development
process using computer aided process planning (CAPP) [9].
In order to start manufacturing planning at conceptual stage, rough methodological
approaches have been suggested. Ashby’s constrained based approach is the most
prevalent one. Alternative process-chains are screened out based on process related
parameters such as material types, shape, size, tolerance, etc. [10], [11]. Compatible
process alternatives are then evaluated based on a rough cost estimation such as re-
source based costing [10], [11]. Detail costing methods, such as ABC costing [12], are
not applicable at conceptual stages since such methods require detail data about the
design [10], [11]. In terms of process planning for quality, the classical capability
index, which is defined as the ratio of dispersion to tolerance (i.e. Cp=T/6σ), is not
suitable during conceptual stages. The Cp is only suitable for medium and large batch
production modes when standard deviations (σ) can be determined [13]. Composite
process capability (CCP) index has been suggested to be used during early phase of
design and when data are not sufficiently available [13]. The details of CCP will be
introduced in Section 4.
In SBCE paradigm, there are alternative set of conceptual designs. For each alter-
native design, there are alternative process chains that should be investigated to be
feasible from manufacturability perspective. Here the challenges and questions are: a)
how designers and process planner can exchange knowledge about the potential solu-
tions? b) how alternative designs and processes can be evaluated in parallel in SBCE
paradigm to reach optimality?
Taking cost and quality as key criteria for process planning, the following section
outlines the steps of the proposed methodology.
4 Proposed Methodology to start Manufacturing Process
Planning in SBCE Paradigm
The proposed methodology is shown in Figure 4. The methodology includes four
steps: a) identification of key quality characteristics for alternative set of designs, b)
planning for process quality using an integrated Quality Function Deployment (QFD)
approach and a Process Failure Mode and Effect Analysis (P-FMEA), c) assessment
of process quality and cost for each set of designs using CCP index and resource
based costing, d) build a decision matrix relating conceptual design alternatives with
respect to process-chain alternatives.
The methodology is designed assuming that designers are following a SBCE para-
digm, and have already explored alternative set of conceptual designs. Moreover, at
the start of the methodology, process planners already have important elements of
manufacturing process alternatives to produce the conceptual designs. Let’s take a
scenario to exemplify the steps of the methodology.
XYZ is a company developing and manufacturing ball bearings in a large scale,
but also offering customized solutions for the automotive industry. XYZ is asked to
supply a new ball bearing for a new automobile model. The designers of XYZ come up
with three alternative bearing concepts: A1, A2 and A3 (see Figure 4). The design
team argue that to investigate the feasibilities of the alternative bearings and select
the optimal one, they need the manufacturability information of the alternatives. At
the same time, the management wants to start designing the manufacturing process in
parallel with the product development to avoid late changes. Manufacturing process
planners roughly identified key process elements required to produce the bearing,
such as, Machining method (MM), Machining tool (MT), and Fixture scheme (FS).
For each process elements they identified process alternatives: Finish or Semi-
finished turning for machining (MM1 or MM2), Vertical or Horizontal lathes for
machining tool (MT1 or MT2), and Final or Outer-clamping (FS1 or FS2) for fixture
scheme respectively. Therefore, in this case we have 3 alternative design concepts
and 8 (2X2X2 )alternative process-routes (process-chains) to evaluate.
Fig. 4. Steps of the proposed methodology
─ Identification of key quality characteristics
Once the sets of alternative of designs and process routes are identified, defining key
design quality characteristics is necessary. Quality characteristics are requirements
specified to fulfill defined customer values. For a specific component or module, key
quality characteristics can be identified either taking similar component family (simi-
lar inheritation) or through expert negotiation (interactive identification). For instance,
co-axiality, contourness of spoke and equilibrium of revolutions are the common
quality characteristics of the ball bearings introduced in the XYZ scenario.
─ Planning for quality
The task of this step is to relate the defined quality characteristics of the conceptual
design sets into process elements and their target levels. To roughly determine the
capability of process alternatives, a team consists of designers, process planners, and
quality engineers should be organized.
Product designers determine the weights of each quality characteristics based on
their experiences about customer needs and design specifications. Using QFD as a
tool to represent the voice of customers, designers can assign the importance of each
quality characteristics. For the scenario mentioned above, assume that the designers
assigned weights of V[0.3, 0.3, 0.4] for the three quality characteristics defined: co-
axiality, contourness of spoke and equilibrium of revolutions respectively.
Process planners and quality engineers can use P-FMEA to estimate the quality
impact of each process elements on the quality characteristics. Based on past experi-
ence and knowledge from historical comment, they can estimate O (Occurrence), S
(Severity), and Detectability (D) of process failures relating a specific quality charac-
teristics and a process element. Then, an aggregate RNP (risk priority num-
ber=O*S*D) value can be obtained from P-FMEA. Depending on the RNP value, the
relationship between process elements and quality characteristics can be scaled on a
QFD matrix from 1-10 (1 very weak relationship and 10 highly related), see Figure 5.
The relative weight of each process elements (W) can be determined using the normal
QFD algorithm [14]. This weight matrix relates the importance of each process ele-
ments (Machining method, fixture scheme etc.) with the defined key quality charac-
teristics.
Fig. 5. An illustration of process planning for quality with a hybrid approach (QFD and Pro-
cess-FMEA)
For each process element the quality measure and level should be defined on the
QFD matrix. For example, the process element measure of machining method is pre-
cision grade. And, for each alternative machining methods the element level can be
defined accordingly. For example, finish and semi-finish turning have precision grade
of 7 and 7.21 IT respectively. Therefore, using the integrated QFD and P-FMEA the
team can prepare all the parameters to determine the composite process capability
index (CCP) for each process alternatives.
─ Assessment of process quality and cost
Cost estimation at conceptual stage is already a matured concept in academia and
industry. Using resource based costing one can determine the process cost of each
design alternatives [10], [11]. Therefore, in this paper, process cost values are as-
sumed to be given. However, the step to determine the quality level of process alter-
natives are not well prevalent, and can be explained as follows:
Step 1. Estimate the capability of process alternatives ( jCe )
Min
j
Max
j
jj
jXX
XXCe
0
+1 (1)
where jCe is the capability index of the jth process alternative of a process element.
jX , 0
jX , Max
jX
and Min
jX are the quality measure, the standard or benchmark, the upper and lower limits of the jth
process alternative respectively. The standard process alternative is generally either an enterprise
standard or a straightforward process alternative with which the team members are very familiar. It
can also be a successfully available process alternative, or an earlier generation of the manufactur-
ing process.
Step 2. Estimate the capability of the quality characteristics (iCp )
j
n
j
ij CewCpi . (2)
Where iCp is the capability of the ith quality characteristics, ijw is the weight of process elements
that relate the ith quality characteristic with the jth process element. And, n is the number of process
elements available.
Step 3. Estimate the composite process capability indexes (CCP) of alternative process
routes
m
i
V
iiCpCCP
1
(3)
Where m is the number of quality characteristics available and Vi is the weight of the ith quality
characteristics.
If we consider the XYZ company scenario again, using step1 it is possible to de-
termine the Cej indexes of alternative process plans, as shown in Table 1.
Using the relative weight found using QFD and P-FMEA, a weight matrix Wij can
be defined as shown in Table 2. Next, using step 2 the team can determine the Cpi
indexes of the quality characteristics as shown in Table 3. The output of this step
shows the capability of each process alternatives (routes or chains) for the defined key
quality characteristics. Since we have 8 possible process chains (2X2X2), each quality
characteristics has 8 possible values of Cp, as shown in Table 3. For example, a design
can go through MM1-MT1-FS1 or MM1-MT1-FS2 possible process chains. Moreo-
ver, using step 3 the aggregate process capability index of alternative process chains
can be determined, assuming the importance of each quality characteristics as Vi [0.3,
0.3, 0.4], see Table 4.
Table 1. Cej indexes of alternative processes
Ce Values
Machining methods (MM) Machine tool (MT) Fixture scheme (FS)
MM1=1.49 MT1=1.11 FS1=1.54
MM2=1.3432 MT2=1.2 FS2=1.55
Table 2. Wij indexes of process elements
Wij Machining methods
(MM)
Machine tool
(MT)
Fixture scheme
(FS)
Coaxiality 0.3 0.2 0.5
Contourness of spoke
0.3333 0.3333 0.333
Equilibrium of
revolution
0.3 0.3 0.4
Table 3. Cp-capabilities of quality characteristics
Cp
MM1-
MT1-FS1
MM1-
MT1-FS2
MM1-
MT2-FS1
MM1-
MT2-FS2
MM2-
MT1-FS1
MM2-
MT1-FS2
MM2-
MT2-FS1
MM2-
MT2-FS2
Coaxiality 1.43 1.44 1.45 1.35 1.26 1.26 1.31 1.31
Contourness
of spoke 1.37 1.38 1.40 1.36 1.33 1.33 1.36 1.36
Equilibrium
of evolution 1.39 1.35 1.42 1.42 1.35 1.35 1.37 1.38
─ Build decision matrix
A decision matrix that relates alternative designs and process chains help designers
and process planners to dialogue while practicing a SBCE process. Since each con-
ceptual product design has particular quality performance and cost structure, the team
should follow the above procedures a, b and c to determine the CCP and cost values
of alternative process chains for each design. Finally, at this stage a decision matrix
can be built to visually represent design and planning spaces, and the team can utilize
to decide an optimal design in parallel with an optimal process plan, as shown in Ta-
ble 5.
Table 4. CCP values of alternative process chains
CCP
MM1-
MT1-FS1
MM1-
MT1-FS2
MM1-
MT2-FS1
MM1-
MT2-FS2
MM2-
MT1-FS1
MM2-
MT1-FS2
MM2-
MT2-FS1
MM2-
MT2-FS2
1.40 1.39 1.43 1.37 1.32 1.32 1.35 1.36
Table 5. Final decision matrix or dialoguing mechanism between designers and process plan-
ners
Alternative
Process Chains
MM1-MT1-
FS1
MM1-MT1-
FS2
MM1-MT2-
FS1
MM1-MT2-
FS2
MM2-MT1-
FS1
MM2-MT1-
FS2
MM2-MT2-
FS1
MM2-MT2-
FS2
A1
CCP1
1.40372
1.38977
1.42899
1.386534
1.31884
1.319461
1.35234
1.3555177
Cost1
-
-
-
-
-
-
-
-
A2
CCP2
1.40000
1.48997
1.32999
1.23653
1.3432
1.2345
1.37234
1.9555177
Cost2
-
-
-
-
-
-
-
-
A3
CCP3
1.30372
1.58977
1.72899
1.386534
1.11884
1.419461
1.65234
1.3555177
Cost3
-
-
-
-
-
-
-
-
5 Conclusion and Future Plan
This paper aims at developing a formal methodology to integrate designers and pro-
cess planners to execute SBCE. Extensive literature review has been made to outline
key manufacturing requirements of SBCE, to understand the key intercept points of
design and manufacturing in SBCE paradigm. The new methodology is based on the
combination of the two prevalent tools, QFD and P-FMEA. The methodology enables
both parties to exchange knowledge about designs and processes in parallel. Moreo-
ver, using CCP and cost indexes, design and process-chain alternatives can be evalu-
ated systematically.
The methodology is under validation in a real case. The next step is to apply it in a
specific SBCE environment.
Acknowledgements
This work was partly funded by the European Commission through the LeanPPD
Project (NMP-2007-214090, www.leanppd.eu). The authors wish to acknowledge
their gratitude and appreciation to the rest of the project partners for their contribu-
tions during the development of various ideas and concepts presented in this paper.
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